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mirror of https://github.com/QuantumPackage/qp2.git synced 2024-12-21 11:03:29 +01:00

added non-sym diag for tc-rpa

This commit is contained in:
Abdallah Ammar 2023-12-22 20:15:58 +01:00
parent 9fc4b6d63b
commit 6235c2015d
7 changed files with 182 additions and 351 deletions

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@ -346,7 +346,7 @@ subroutine davidson_general_ext_rout_nonsym_b1space(u_in, H_jj, energies, sze, N
endif
if(i_omax(l) .ne. l) then
print *, ' !!! WARNONG !!!'
print *, ' !!! WARNING !!!'
print *, ' index of state', l, i_omax(l)
endif
enddo

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@ -0,0 +1,114 @@
program print_scf_int
call main()
end
subroutine main()
implicit none
integer :: i, j, k, l
print *, " Hcore:"
do j = 1, ao_num
do i = 1, ao_num
print *, i, j, ao_one_e_integrals(i,j)
enddo
enddo
print *, " P:"
do j = 1, ao_num
do i = 1, ao_num
print *, i, j, SCF_density_matrix_ao_alpha(i,j)
enddo
enddo
double precision :: integ, density_a, density_b, density
double precision :: J_scf(ao_num, ao_num)
double precision :: K_scf(ao_num, ao_num)
double precision, external :: get_ao_two_e_integral
PROVIDE ao_integrals_map
print *, " J:"
!do j = 1, ao_num
! do l = 1, ao_num
! do i = 1, ao_num
! do k = 1, ao_num
! ! < 1:k, 2:l | 1:i, 2:j >
! print *, '< k l | i j >', k, l, i, j
! print *, get_ao_two_e_integral(i, j, k, l, ao_integrals_map)
! enddo
! enddo
! enddo
!enddo
!do k = 1, ao_num
! do i = 1, ao_num
! do j = 1, ao_num
! do l = 1, ao_num
! ! ( 1:k, 1:i | 2:l, 2:j )
! print *, '(k i | l j)', k, i, l, j
! print *, get_ao_two_e_integral(l, j, k, i, ao_integrals_map)
! enddo
! enddo
! print *, ''
! enddo
!enddo
J_scf = 0.d0
K_scf = 0.d0
do i = 1, ao_num
do k = 1, ao_num
do j = 1, ao_num
do l = 1, ao_num
density_a = SCF_density_matrix_ao_alpha(l,j)
density_b = SCF_density_matrix_ao_beta (l,j)
density = density_a + density_b
integ = get_ao_two_e_integral(l, j, k, i, ao_integrals_map)
J_scf(k,i) += density * integ
integ = get_ao_two_e_integral(l, i, k, j, ao_integrals_map)
K_scf(k,i) -= density_a * integ
enddo
enddo
enddo
enddo
print *, 'J x P'
do i = 1, ao_num
do k = 1, ao_num
print *, k, i, J_scf(k,i)
enddo
enddo
print *, ''
print *, 'K x P'
do i = 1, ao_num
do k = 1, ao_num
print *, k, i, K_scf(k,i)
enddo
enddo
print *, ''
print *, 'F in AO'
do i = 1, ao_num
do k = 1, ao_num
print *, k, i, Fock_matrix_ao(k,i)
enddo
enddo
print *, ''
print *, 'F in MO'
do i = 1, ao_num
do k = 1, ao_num
print *, k, i, 2.d0 * Fock_matrix_mo_alpha(k,i)
enddo
enddo
end

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@ -1883,8 +1883,13 @@ subroutine check_biorthog(n, m, Vl, Vr, accu_d, accu_nd, S, thr_d, thr_nd, stop_
enddo
accu_nd = dsqrt(accu_nd) / dble(m)
if((accu_nd .gt. thr_nd) .or. dabs(accu_d-dble(m))/dble(m) .gt. thr_d) then
print *, ' non bi-orthogonal vectors !'
print *, ' accu_nd = ', accu_nd
print *, ' accu_d = ', dabs(accu_d-dble(m))/dble(m)
else
print *, ' vectors are bi-orthogonaly'
endif
! ---
@ -1994,10 +1999,13 @@ subroutine reorder_degen_eigvec(n, e0, L0, R0)
ii = ii + 1
endif
enddo
if(ii .eq. 0) then
print*, ' WARNING: bi-orthogonality is lost but there is no degeneracies'
print*, ' rotations may change energy'
stop
endif
print *, ii, ' type of degeneracies'
! ---
@ -2018,8 +2026,9 @@ subroutine reorder_degen_eigvec(n, e0, L0, R0)
call dgemm( 'T', 'N', m, m, n, 1.d0 &
, L, size(L, 1), R, size(R, 1) &
, 0.d0, S, size(S, 1) )
print*, 'Overlap matrix '
accu_nd = 0.D0
accu_nd = 0.d0
do j = 1, m
write(*,'(100(F16.10,X))') S(1:m,j)
do k = 1, m
@ -2043,6 +2052,8 @@ subroutine reorder_degen_eigvec(n, e0, L0, R0)
end subroutine reorder_degen_eigvec
! ---
subroutine impose_biorthog_degen_eigvec(n, e0, L0, R0)
implicit none
@ -2108,8 +2119,10 @@ subroutine impose_biorthog_degen_eigvec(n, e0, L0, R0)
! ---
! call impose_orthog_svd(n, m, L)
call impose_orthog_svd(n, m, R)
L(:,:) = R(:,:)
!call impose_orthog_svd(n, m, L)
!call impose_orthog_GramSchmidt(n, m, L)
!call impose_orthog_GramSchmidt(n, m, R)
@ -2128,7 +2141,7 @@ subroutine impose_biorthog_degen_eigvec(n, e0, L0, R0)
!call bi_ortho_s_inv_half(m, L, R, S_inv_half)
!deallocate(S, S_inv_half)
call impose_biorthog_svd(n, m, L, R)
!call impose_biorthog_svd(n, m, L, R)
!call impose_biorthog_inverse(n, m, L, R)
!call impose_biorthog_qr(n, m, thr_d, thr_nd, L, R)

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@ -1,116 +0,0 @@
BEGIN_PROVIDER [double precision, M_RPA, (2*nS_exc, 2*nS_exc)]
BEGIN_DOC
!
! full matrix for direct RPA calculation
! with the TC-Hamiltonian
!
END_DOC
implicit none
integer :: ia, i, a, jb, j, b
double precision :: e(mo_num)
double precision, external :: Kronecker_delta
PROVIDE mo_tc_effec2e_int
PROVIDE Fock_matrix_tc_diag_mo_tot
e(1:mo_num) = Fock_matrix_tc_diag_mo_tot(1:mo_num)
! --- --- ---
! block A
ia = 0
do i = nC_orb+1, nO_orb
do a = nO_orb+1, mo_num-nR_orb
ia = ia + 1
jb = 0
do j = nC_orb+1, nO_orb
do b = nO_orb+1, mo_num-nR_orb
jb = jb + 1
M_RPA(ia,jb) = (e(a) - e(i)) * Kronecker_delta(i,j) * Kronecker_delta(a,b) + 2.d0 * mo_tc_effec2e_int(a,j,i,b)
enddo
enddo
enddo
enddo
!
! --- --- ---
! --- --- ---
! block B
ia = 0
do i = nC_orb+1, nO_orb
do a = nO_orb+1, mo_num-nR_orb
ia = ia + 1
jb = nS_exc
do j = nC_orb+1, nO_orb
do b = nO_orb+1, mo_num-nR_orb
jb = jb + 1
M_RPA(ia,jb) = 2.d0 * mo_tc_effec2e_int(a,b,i,j)
enddo
enddo
enddo
enddo
!
! --- --- ---
! --- --- ---
! block C
ia = nS_exc
do i = nC_orb+1, nO_orb
do a = nO_orb+1, mo_num-nR_orb
ia = ia + 1
jb = 0
do j = nC_orb+1, nO_orb
do b = nO_orb+1, mo_num-nR_orb
jb = jb + 1
M_RPA(ia,jb) = 2.d0 * mo_tc_effec2e_int(i,j,a,b)
enddo
enddo
enddo
enddo
!
! --- --- ---
! --- --- ---
! block D
ia = nS_exc
do i = nC_orb+1, nO_orb
do a = nO_orb+1, mo_num-nR_orb
ia = ia + 1
jb = nS_exc
do j = nC_orb+1, nO_orb
do b = nO_orb+1, mo_num-nR_orb
jb = jb + 1
M_RPA(ia,jb) = (e(a) - e(i)) * Kronecker_delta(i,j) * Kronecker_delta(a,b) + 2.d0 * mo_tc_effec2e_int(i,b,a,j)
enddo
enddo
enddo
enddo
!
! --- --- ---
END_PROVIDER

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@ -1,39 +0,0 @@
BEGIN_PROVIDER [double precision, mo_tc_effec2e_int, (mo_num, mo_num, mo_num, mo_num)]
BEGIN_DOC
!
! mo_tc_effec2e_int(p,q,s,t) = < p q| V(12) | s t > + \sum_i < p q i | L(123)| s t i >
!
! the potential V(12) contains ALL TWO-E CONTRIBUTION OF THE TC-HAMILTONIAN
!
END_DOC
implicit none
integer :: i, j, k, l, ii
double precision :: integral
PROVIDE mo_bi_ortho_tc_two_e_chemist
do j = 1, mo_num
do i = 1, mo_num
do l = 1, mo_num
do k = 1, mo_num
mo_tc_effec2e_int(k,l,i,j) = mo_bi_ortho_tc_two_e_chemist(k,i,l,j)
do ii = 1, elec_alpha_num
call give_integrals_3_body_bi_ort(k, l, ii, i, j, ii, integral)
mo_tc_effec2e_int(k,l,i,j) -= 2.d0 * integral
enddo
enddo
enddo
enddo
enddo
FREE mo_bi_ortho_tc_two_e_chemist
END_PROVIDER
! ---

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@ -1,181 +0,0 @@
program tc_rpa
BEGIN_DOC
!
!
!
END_DOC
my_grid_becke = .True.
PROVIDE tc_grid1_a tc_grid1_r
my_n_pt_r_grid = tc_grid1_r
my_n_pt_a_grid = tc_grid1_a
touch my_grid_becke my_n_pt_r_grid my_n_pt_a_grid
if(j1b_type .ge. 100) then
my_extra_grid_becke = .True.
PROVIDE tc_grid2_a tc_grid2_r
my_n_pt_r_extra_grid = tc_grid2_r
my_n_pt_a_extra_grid = tc_grid2_a
touch my_extra_grid_becke my_n_pt_r_extra_grid my_n_pt_a_extra_grid
call write_int(6, my_n_pt_r_extra_grid, 'radial internal grid over')
call write_int(6, my_n_pt_a_extra_grid, 'angular internal grid over')
endif
call main()
end
! ---
subroutine main()
implicit none
integer :: i, j, n
integer :: n_good, n_real_eigv
double precision :: thr_cpx, thr_d, thr_nd
double precision :: accu_d, accu_nd
integer, allocatable :: list_good(:), iorder(:)
double precision, allocatable :: WR(:), WI(:), VL(:,:), VR(:,:)
double precision, allocatable :: Omega_p(:), Reigvec_p(:,:), Leigvec_p(:,:)
double precision, allocatable :: Omega_m(:), Reigvec_m(:,:), Leigvec_m(:,:)
double precision, allocatable :: S(:,:)
PROVIDE M_RPA
print *, ' '
print *, ' Computing left/right eigenvectors for TC-RPA ...'
print *, ' '
n = 2 * nS_exc
thr_cpx = 1d-7
thr_d = 1d-07
thr_nd = 1d-07
allocate(WR(n), WI(n), VL(n,n), VR(n,n))
call lapack_diag_non_sym(n, M_RPA, WR, WI, VL, VR)
FREE M_RPA
print *, ' excitation energies:'
do i = 1, nS_exc
write(*, '(I3, X, 1000(F16.10,X))') i, WR(i), WI(i)
if(dabs(WI(i)) .gt. thr_cpx) then
print *, ' WARNING ! IMAGINARY EIGENVALUES !!!'
write(*, '(1000(F16.10,X))') WR(i), WI(i+1)
endif
enddo
print *, ' '
print *, ' desexcitation energies:'
do i = nS_exc+1, n
write(*, '(I3, X, 1000(F16.10,X))') i, WR(i), WI(i)
if(dabs(WI(i)) .gt. thr_cpx) then
print *, ' WARNING ! IMAGINARY EIGENVALUES !!!'
write(*, '(1000(F16.10,X))') WR(i), WI(i+1)
endif
enddo
! track & sort the real eigenvalues
n_good = 0
do i = 1, nS_exc
if(dabs(WI(i)) .lt. thr_cpx) then
if(dabs(WI(nS_exc+i)) .lt. thr_cpx) then
n_good += 1
endif
endif
enddo
n_real_eigv = n_good
print *, ' '
print *, ' nb of real eigenvalues = ', n_real_eigv
print *, ' total nb of eigenvalues = ', nS_exc
allocate(Omega_p(n_real_eigv), Reigvec_p(n,n_real_eigv), Leigvec_p(n,n_real_eigv))
allocate(Omega_m(n_real_eigv), Reigvec_m(n,n_real_eigv), Leigvec_m(n,n_real_eigv))
n_good = 0
do i = 1, nS_exc
if(dabs(WI(i)) .lt. thr_cpx) then
if(dabs(WI(nS_exc+i)) .lt. thr_cpx) then
n_good += 1
Omega_p(n_good) = WR(i)
do j = 1, n
Reigvec_p(j,n_good) = VR(j,n_good)
Leigvec_p(j,n_good) = VL(j,n_good)
enddo
Omega_m(n_good) = WR(nS_exc+i)
do j = 1, n
Reigvec_m(j,n_good) = VR(j,nS_exc+n_good)
Leigvec_m(j,n_good) = VL(j,nS_exc+n_good)
enddo
endif
endif
enddo
deallocate(WR, WI, VL, VR)
! check bi-orthogonality
! first block
allocate(S(n_real_eigv,n_real_eigv))
call check_biorthog(n, n_real_eigv, Leigvec_p, Reigvec_p, accu_d, accu_nd, S, thr_d, thr_nd, .false.)
print *, ' accu_d = ', accu_d
print *, ' accu_nd = ', accu_nd
if((accu_nd .lt. thr_nd) .and. (dabs(accu_d-dble(n_real_eigv))/dble(n_real_eigv) .lt. thr_d)) then
print *, ' RPA first-block eigenvectors are normalized and bi-orthogonalized'
else
print *, ' RPA first-block eigenvectors are neither normalized nor bi-orthogonalized'
call reorder_degen_eigvec(n, Omega_p, Leigvec_p, Reigvec_p)
call impose_biorthog_degen_eigvec(n, Omega_p, Leigvec_p, Reigvec_p)
call check_biorthog(n, n_real_eigv, Leigvec_p, Reigvec_p, accu_d, accu_nd, S, thr_d, thr_nd, .false.)
if( (accu_nd .lt. thr_nd) .and. (dabs(accu_d-dble(n_real_eigv)) .gt. thr_d) ) then
call check_biorthog_binormalize(n, n_real_eigv, Leigvec_p, Reigvec_p, thr_d, thr_nd, .true.)
endif
call check_biorthog(n, n_real_eigv, Leigvec_p, Reigvec_p, accu_d, accu_nd, S, thr_d, thr_nd, .true.)
endif
! second block
call check_biorthog(n, n_real_eigv, Leigvec_m, Reigvec_m, accu_d, accu_nd, S, thr_d, thr_nd, .false.)
print *, ' accu_d = ', accu_d
print *, ' accu_nd = ', accu_nd
if((accu_nd .lt. thr_nd) .and. (dabs(accu_d-dble(n_real_eigv))/dble(n_real_eigv) .lt. thr_d)) then
print *, ' RPA first-block eigenvectors are normalized and bi-orthogonalized'
else
print *, ' RPA first-block eigenvectors are neither normalized nor bi-orthogonalized'
call reorder_degen_eigvec(n, Omega_m, Leigvec_m, Reigvec_m)
call impose_biorthog_degen_eigvec(n, Omega_m, Leigvec_m, Reigvec_m)
call check_biorthog(n, n_real_eigv, Leigvec_m, Reigvec_m, accu_d, accu_nd, S, thr_d, thr_nd, .false.)
if( (accu_nd .lt. thr_nd) .and. (dabs(accu_d-dble(n_real_eigv)) .gt. thr_d) ) then
call check_biorthog_binormalize(n, n_real_eigv, Leigvec_m, Reigvec_m, thr_d, thr_nd, .true.)
endif
call check_biorthog(n, n_real_eigv, Leigvec_m, Reigvec_m, accu_d, accu_nd, S, thr_d, thr_nd, .true.)
endif
deallocate(S)
return
end
! ---

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@ -600,3 +600,43 @@ end function Kronecker_delta
! ---
subroutine diagonalize_sym_matrix(N, A, e)
BEGIN_DOC
!
! Diagonalize a symmetric matrix
!
END_DOC
implicit none
integer, intent(in) :: N
double precision, intent(inout) :: A(N,N)
double precision, intent(out) :: e(N)
integer :: lwork, info
double precision, allocatable :: work(:)
allocate(work(1))
lwork = -1
call dsyev('V', 'U', N, A, N, e, work, lwork, info)
lwork = int(work(1))
deallocate(work)
allocate(work(lwork))
call dsyev('V', 'U', N, A, N, e, work, lwork, info)
deallocate(work)
if(info /= 0) then
print*,'Problem in diagonalize_sym_matrix (dsyev)!!'
endif
end subroutine diagonalize_sym_matrix
! ---